PL168457B1 - Garbage incineration method and plant therefor - Google Patents

Abstract

Heat production is equalised in incineration plants with changing fuel quality. A multi-loop control system is used for this purpose. The amount of steam produced is used as the main control variable, and the oxygen content in the flue gas as the auxiliary control variable. Further parameters in the operation of an incineration plant can be improved by this method. <IMAGE>

Description

The subject of the invention is a waste incineration device with a combustion chamber equipped with a grate, a boiler and a combustion regulation system.

Operation, and especially the uniform heat generation in oil or coal-fired power plants, poses no problems. They are obtained by uniformly dosing the amount of fuel, the quality of which is constant and known.

Also in refuse incinerators, apart from keeping the quality and quantity of exhaust gases constant, the main goal is to maintain a constant value of the thermal power. It is not possible to control the heat output only by dosing in garbage or waste incinerators, since their composition and therefore the calorific value of the fuel input, from glass to paper to moist garden waste, varies considerably over time. Thus, it becomes problematic to maintain a constant value of the amount of heat produced, and hence steam. It becomes even more problematic to maintain a constant value of generated heat if one wants to optimize other parameters, e.g. the quality of exhaust gases.

According to the known method, attempts were made to keep the heat generated constant on the basis of steam quantity measurements. This kind of treatment was not satisfactory. This resulted in large amplitude fluctuations in the values.

It is known that with a greater proportion of combustible material in the waste to be burned, more oxygen is used in the combustion chamber for combustion. As a result, there is less oxygen in the exhaust gas. This fact has already been used by G. Schretter and E. Leitmeir. They described in the publication VGB Kraftwerkstechnik 1987 pp. 132,133 a combustion control in which the disturbing quantity in the form of a changing composition of the garbage has been removed so far that a relatively uniform combustion course is ensured. For this purpose, it was proposed to use three independent control circuits, the authors of which have already tried out the first two and the third as a working project.

In the first control circuit, the garbage throughput is controlled based on the oxygen content of the exhaust gas, which is a controlled variable.

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In the second control circuit, the quantity of steam is used as the control variable which influences the supply of the first air. The control circuit 3 under development would be designed to introduce secondary air into the control process.

This known control method is laborious and does not ensure the uniformity in the production of heat, and therefore the amount of steam, to the extent required in practice. Optimizing other parameters is not taken into account at all.

The object of the present invention is therefore to provide a waste incineration device in which, with economically acceptable expenditure, it is possible to homogenize the heat generation and thus maintain a constant amount of steam produced, and in which it would be possible to optimize processes in waste incinerators equipped with grates as needed. . This task is solved in that the waste incinerator according to the invention is characterized in that the regulating system has a slow main regulator for regulating the amount of steam as the main controlled variable, to which are connected at least three quick auxiliary regulators to which it is supplied. the mixed oxygen content as an auxiliary control variable, the outputs of which are connected to the actuating members of the pusher, grate and primary air flaps.

Preferably, in the device according to the invention, an auxiliary controller is connected to three auxiliary controllers, to which the device for measuring the temperature of the firebox roof is connected as an auxiliary regular quantity.

In addition, an additional auxiliary controller is connected to the three auxiliary controllers with which the device for measuring the temperature of the grate is connected as an auxiliary controlled quantity.

The first air flap actuators assigned to the auxiliary controller are connected to the secondary air control, keeping the total amount of combustion air constant.

Multi-circuit control devices or control circuits are known in the art. They are also known as the so-called cascade control. It is at least a two-circuit control system, one or more auxiliary circuits in the main circuit.

A slow-acting PI-controller is used as the main controller or lead controller, to which a fast-acting P controller is connected as a slave or follower controller.

According to the invention, in cascade control, the main control variable is the amount of steam produced, which is set with a certain delay. A rapidly available value for the oxygen content in the exhaust gas is used as an auxiliary control variable. Since this quantity is available practically without delay, the control variable can be influenced directly in the auxiliary cascade control circuit.

By means of the setting variables set by the auxiliary regulators, the pusher, grate and primary air flap are preferably controlled, i.e. the refuse feed into the combustion chamber, the refuse flow through the furnace and the combustion air supply.

By using the device according to the invention, uniformity is achieved, i.e. the value of heat production and therefore the amount of steam are kept constant. In addition, other combustion parameters can be optimized, e.g. flue gas quality, slag quality, grate life and combustion chamber temperature. At the same time, a constant amount of smoke and its quality are obtained.

Other controllable variables that can be regulated are the temperature of the firebox roof and the temperature of the grate, the introduction of which into additional auxiliary control circuits allows for the improvement of the control process and thus the elimination of small fluctuations in the amount of steam.

Temperature measurement at the top of the firebox and at the grate offers further significant advantages. This is clearly visible when we take into account that the process taking place on the grate usually lasts about an hour and so far it was controlled by the operating personnel only by feeling. Therefore, according to the invention, it is possible for the first time to regulate the combustion process on the grate on the basis of actual conditions. The individual advantages of entering the ceiling temperature

168 457 firebox and grate are expressed by the maximum use of the grate surface, extended service life of the grate, better burning of the exhaust gases, better quality of the exhaust gases and more economical excess air.

If the temperature of the firebox roof is too high, the pusher and with it the waste feed is released. The coverage of the grate is thereby reduced, i.e. the grate is less insulated and the temperature of the grate rises, as a result of which the speed of the grate is reduced in order to maintain a higher degree of coverage. At the same time, the amount of primary air also decreases, and the amount of secondary air increases accordingly.

The subject of the invention is shown in an embodiment in the drawing, in which; Fig. 1 is a schematic diagram of a process in a refuse incinerator, and Fig. 2 is a diagram of one embodiment of regulation in a device according to the invention.

Debris is supplied to the combustion chamber 1 (not shown in detail) in Fig. 1 by the pusher 2. The dosing is a function of the speed of the pusher. The delivered garbage enters a driven grate for incineration (not shown in more detail), where it is dried, degassed and incinerated. The primary air influences the combustion process. The hot exhaust gases 3 pass from the combustion chamber 1 to the boiler 4, where they are used to generate steam. The cooled exhaust gases 5 and steam 6 leave the boiler 4. The measured values for steam 8, oxygen content 9 in the flue gas and, if necessary, the temperature of the top of the firebox 11 and the grate are fed to the control system 7 for constant efficiency or optimization of the efficiency.

12. The control system sends setting signals 13 to the dosing pusher, to the grate and to the primary air flaps.

The control system shown in Fig. 2 has known measuring devices 14, 15, 16, 17 for measuring the amount of steam, oxygen in the exhaust gas, temperature of the top of the firebox and the grate.

The measured value of the amount of steam is fed as input 18, to the main controller or to the lead controller 19. This is a slow PI controller. Its output signal 27 is fed to three auxiliary or follower regulators 21, 22, 23 connected. These are fast-acting P regulators.

The desired value of the auxiliary controllers 21, 22, 23 is set by the output signal 27 of the main controller based on the measured parameters of the pair. To the auxiliary controllers 2122.23, a measured value for the oxygen (O2) contained in the exhaust gas is supplied as input 20. This is done directly as oxygen is measured immediately. The outputs of each of the auxiliary regulators 21, 22, 23 are connected to one of the actuating members, i.e. a pusher 24 for dispensing refuse, a grate 25 for determining the residence time of the refuse on the grate, and a primary air flap 26 for supplying combustion air. The actuating signals 32, 33, 34 of the auxiliary controllers 21, 22, 23 are in practice fed immediately to the actuating members 24, 25, 26.

According to a particularly advantageous embodiment of the invention, the combustion chamber temperature and / or the grate temperature are measured by means of suitable measuring devices 16, 17. The measured value is fed as an input signal 35, 36 to the respective auxiliary controllers 37, 38, whose output signals 39, 41 are fed to the auxiliary controllers 21, 22, 23. In this way, it is ensured that the value is kept constant and the heat generation in the device is optimized. for burning garbage.

Moreover, the auxiliary controller 23 for the primary air can be combined with the control for the secondary air for better effects. In this way, the amount of secondary air can be controlled such that the sum of the primary air and the secondary air, i.e. the total amount of combustion air, remains constant.

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Publishing Department of the UP RP. Circulation of 90 copies. Price PLN 1.50

Claims (4)

Patent claims 1. A waste incineration device with a combustion chamber equipped with a grate, a boiler and a combustion control system containing measuring devices for measuring the amount of water vapor and oxygen content in the flue gas as controlled quantities, characterized in that the control system has a slow main regulator (19) for controlling the amount of steam (18) as the main controlled variable to which at least three fast auxiliary regulators (21, 22, 23) are connected to which the measured oxygen content (20) is supplied as an auxiliary control variable, the outputs of which are connected with the setting members of the pusher (24), grate (25) and first air flaps (26). 2. The device according to claim The apparatus of claim 1, characterized in that an auxiliary controller (37) is connected to the three auxiliary controllers (21, 22, 23), to which the device for measuring the temperature (16) of the top of the firebox (11) is connected as an auxiliary control variable. 3. The device according to claim The device of claim 1, characterized in that an additional auxiliary controller (38) is connected to the three auxiliary controllers (21, 22, 23), to which a device for measuring the temperature (17) of the grate (12) is connected as an auxiliary controlled variable. 4. The device according to claim The primary air flap actuator (26) as claimed in claim 1, associated with the auxiliary controller (23), is connected to the secondary air control, keeping the total amount of combustion air constant.